Abstract: An integrated device package that includes a die, a substrate, a fill and a conductive interconnect. The die includes a pillar, where the pillar has a first pillar width. The substrate (e.g., package substrate, interposer) includes a dielectric layer and a substrate interconnect (e.g., surface interconnect, embedded interconnect). The fill is located between the die and the substrate. The conductive interconnect is located within the fill. The conductive interconnect includes a first interconnect width that is about the same or less than the first pillar width. The conductive interconnect is coupled to the pillar and the substrate interconnect. The fill is a non-conductive photosensitive material. The fill is a photosensitive film. The substrate interconnect includes a second interconnect width that is equal or greater than the first pillar width. The conductive interconnect includes one of at least a paste, a solder and/or an enhanced solder comprising a polymeric material.

Abstract: Some features pertain to a package that includes a redistribution portion, a first die coupled to the redistribution portion, a core layer coupled to the redistribution portion, and an encapsulation layer encapsulating the first die and the core layer. The redistribution portion includes a first dielectric layer. The core layer has a higher Young's Modulus than the encapsulation layer. In some implementations, the core layer includes a glass fiber (e.g., core layer is a glass reinforced dielectric layer). In some implementations, the core layer has a Young's Modulus of about at least 15 gigapascals (Gpa). In some implementations, the first die includes a front side and a back side, where the front side of the first die is coupled to the redistribution portion. In some implementations, the first dielectric layer is a photo imageable dielectric (PID) layer.

Abstract: An integrated circuit package includes a substrate/interposer assembly having a plurality of conductive contacts and a plurality of conductive posts, such as copper posts, electrically coupled to at least some of the conductive contacts in the substrate/interposer assembly. The conductive posts are surrounded by a protective dielectric, such as a photoimageable dielectric (PID). An integrated circuit die may be disposed on the substrate/interposer assembly within an interior space surrounded by the dielectric. An additional integrated circuit die may be provided in a package-on-package (POP) configuration.

Abstract: A semiconductor package may include a lower substrate with one or more electronic components attached to a surface thereof and an upper substrate with one or more cavities wherein the upper substrate is attached to the lower substrate at a plurality of connection points with the one or more electronic components fitting within a single cavity or a separate cavity for each component that allow the overall form factor of the semiconductor package to remain smaller. The plurality of connection points provide a mechanical and electrical connection between the upper and lower substrate and may include solder joints there between as well as conductive filler particles that create an adhesive reinforcement matrix when compressed for assembly.

Abstract: Some features pertain to a package that includes a redistribution portion, a first die coupled to the redistribution portion, a core layer coupled to the redistribution portion, and an encapsulation layer encapsulating the first die and the core layer. The redistribution portion includes a first dielectric layer. The core layer has a higher Young's Modulus than the encapsulation layer. In some implementations, the core layer includes a glass fiber (e.g., core layer is a glass reinforced dielectric layer). In some implementations, the core layer has a Young's Modulus of about at least 15 gigapascals (Gpa). In some implementations, the first die includes a front side and a back side, where the front side of the first die is coupled to the redistribution portion. In some implementations, the first dielectric layer is a photo imageable dielectric (PID) layer.

Abstract: To achieve a package-on-package having an advantageously reduced height, a first package substrate has a window sized to receive a second package die. The first package substrate interconnects to the second package substrate through a plurality of package-to-package interconnects such that the first and second substrates are separated by a gap. The second package die has a thickness greater than the gap such that the second package die is at least partially disposed within the first package substrate's window.

Abstract: Some novel features pertain to an integrated device that includes a substrate, a first via, and a first bump pad. The first via traverses the substrate. The first via has a first via dimension. The first bump pad is on a surface of the substrate. The first bump pad is coupled to the first via. The first bump pad has a first pad dimension that is equal or less then the first via dimension. In some implementations, the integrated device includes a second via and a second bump pad. The second via traverses the substrate. The second via has a second via dimension. The second bump pad is on the surface of the substrate. The second bump pad is coupled to the second via. The second bump pad has a second pad dimension that is equal or less then the second via dimension.

Abstract: An integrated circuit package includes a substrate/interposer assembly having a plurality of conductive contacts and a plurality of conductive posts, such as copper posts, electrically coupled to at least some of the conductive contacts in the substrate/interposer assembly. The conductive posts are surrounded by a protective dielectric, such as a photoimageable dielectric (PID). An integrated circuit die may be disposed on the substrate/interposer assembly within an interior space surrounded by the dielectric. An additional integrated circuit die may be provided in a package-on-package (POP) configuration.

Abstract: A semiconductor package may include a lower substrate with one or more electronic components attached to a surface thereof and an upper substrate with one or more cavities wherein the upper substrate is attached to the lower substrate at a plurality of connection points with the one or more electronic components fitting within a single cavity or a separate cavity for each component that allow the overall form factor of the semiconductor package to remain smaller. The plurality of connection points provide a mechanical and electrical connection between the upper and lower substrate and may include solder joints there between as well as conductive filler particles that create an adhesive reinforcement matrix when compressed for assembly.

Abstract: A semiconductor package for a side by side die configuration may include a substrate having a cavity, a bridge interposer positioned within the cavity and having an active side facing active sides of a first die and a second die and partially horizontally overlapping the first die and the second die to provide an interconnection between the first die and the second die, and a thermal element attached to backsides of the first die and the second die to provide a heat path and heat storage for the first die and the second die.

Abstract: An integrated device package that includes a die, a substrate, a fill and a conductive interconnect. The die includes a pillar, where the pillar has a first pillar width. The substrate (e.g., package substrate, interposer) includes a dielectric layer and a substrate interconnect (e.g., surface interconnect, embedded interconnect). The fill is located between the die and the substrate. The conductive interconnect is located within the fill. The conductive interconnect includes a first interconnect width that is about the same or less than the first pillar width. The conductive interconnect is coupled to the pillar and the substrate interconnect. The fill is a non-conductive photosensitive material. The fill is a photosensitive film. The substrate interconnect includes a second interconnect width that is equal or greater than the first pillar width. The conductive interconnect includes one of at least a paste, a solder and/or an enhanced solder comprising a polymeric material.

Abstract: A backside mold configuration (BSMC) process for manufacturing packaged integrated circuits includes applying a mold compound to a side of a packaging substrate opposite an attached die. The mold compound is deposited on a dielectric (such as photo resist). The mold compound and dielectric are patterned after coupling a die to the packaging substrate to expose a contact pad of the packaging substrate. After patterning the mold compound and dielectric, a packaging connection is coupled to contact pads through the mold compound and dielectric. The mold compound surrounding the packaging connection reduces warpage of the packaging substrate during processing. Additionally, patterning the dielectric after attaching the die improves reliability of the packaging connection.

Abstract: Methods and apparatus for cavity formation in a semiconductor package substrate are provided. In one embodiment, a method for producing at least one cavity within a semiconductor package substrate includes etching the semiconductor package substrate from a surface of the semiconductor package substrate at least one intended cavity location in order to obtain at least one cavity. The method includes depositing a copper portion on a substrate in a cavity location. Next, the method includes masking the substrate while keeping the copper portion exposed. Lastly, the method includes etching the substrate to form a cavity by etching away the copper portion. The structure formed includes a cavity that extends partially through the substrate without damaging a glass fabric embedded in the substrate.

Abstract: Some novel features pertain to an integrated device that includes a substrate, a first via, and a first bump pad. The first via traverses the substrate. The first via has a first via dimension. The first bump pad is on a surface of the substrate. The first bump pad is coupled to the first via. The first bump pad has a first pad dimension that is equal or less then the first via dimension. In some implementations, the integrated device includes a second via and a second bump pad. The second via traverses the substrate. The second via has a second via dimension. The second bump pad is on the surface of the substrate. The second bump pad is coupled to the second via. The second bump pad has a second pad dimension that is equal or less then the second via dimension.

Abstract: Some implementations provide a semiconductor device that includes a die, an under bump metallization (UBM) structure coupled to the die, and a barrier layer. The UBM structure has a first oxide property. The barrier layer has a second oxide property that is more resistant to oxide removal from a flux material than the first oxide property of the UBM structure. The barrier layer includes a top portion, a bottom portion and a side portion. The top portion is coupled to the UBM structure, and the side portion is substantially oxidized.

Abstract: A backside mold configuration (BSMC) process for manufacturing packaged integrated circuits includes applying a mold compound to a side of a packaging substrate opposite an attached die. The mold compound is deposited on a dielectric (such as photo resist). The mold compound and dielectric are patterned after coupling a die to the packaging substrate to expose a contact pad of the packaging substrate. After patterning the mold compound and dielectric, a packaging connection is coupled to contact pads through the mold compound and dielectric. The mold compound surrounding the packaging connection reduces warpage of the packaging substrate during processing. Additionally, patterning the dielectric after attaching the die improves reliability of the packaging connection.